2.1 Initial field in the focus in the frequency–space domain

We assume the laser frequency spectrum and transverse profile to be Gaussian in the focus:

$$\begin{align*}\widehat{E}\left(x,z=0,\Omega \right)&={\epsilon}_{\Omega}{\epsilon}_x{e}^{- i\varphi},\\{\epsilon}_{\Omega}\left(\Omega \right)&={e}^{-\frac{\tau_0^2}{4}{\left(\Omega -{\Omega}_0\right)}^2},\\ {\epsilon}_x(x)&={e}^{-\frac{{\left(x-{x}_0\right)}^2}{w_0^2}},\end{align*}$$

where $\varphi =\varphi \left(x,z=0,\Omega \right)$ is the initial spectral phase of the pulse, $\Omega =2\pi \nu$ is the angular frequency, ${\Omega}_0$ is the central laser frequency, $\left(x,z\right)$ is the position considered with $z=0$ marking the focus, ${\tau}_0={\tau}_{\mathrm{FWHM},\mathrm{I}}/\sqrt{2\ln 2}$ is the Fourier limited duration, ${\tau}_{\mathrm{FWHM},\mathrm{I}}$ is the full width at half maximum of the field’s time–space domain longitudinal intensity distribution, ${w}_0={w}_{\mathrm{FWHM},\mathrm{I}}/\sqrt{2\ln 2}$ is the focal width of the transverse spatial distribution of frequency $\Omega$ , ${w}_{\mathrm{FWHM},\mathrm{I}}$ is the focal full width at half maximum of the undisturbed pulse’s time–space domain transverse spatial intensity distribution and ${x}_0={x}_0\left(\Omega \right)$ is the center position of the spatial distribution of frequency $\Omega$ in the focus. The latter is related to spatial dispersion $\mathrm{SD}$ , being defined as the coefficient of the linear term in the expansion of the transverse frequency distribution center ${x}_{\mathrm{c}}$ with respect to frequency:

(1) $$\begin{align}\mathrm{SD}:= {\left.\frac{\mathrm{d}{x}_{\mathrm{c}}}{\mathrm{d}\Omega}\right|}_{\Omega ={\Omega}_0}.\end{align}$$

Since ${x}_0={x}_{\mathrm{c}}\left(z=0\right)$ , the initial value of spatial dispersion at $z=0$ is $\mathrm{SD}_{\mathrm{foc}}={x}_0^{\prime }$ .

The laser’s spectral phase $\varphi \left(x,z=0,\Omega \right)$ in the focus is defined by the existence of angular dispersion in the focus $\mathrm{AD}_{\mathrm{foc}}$ . Angular dispersion manifests in the divergence of propagation directions between frequencies, where the propagation directions of frequency $\Omega$ and the central laser frequency ${\Omega}_0$ enclose the angle $\theta =\theta \left(\Omega \right)$ . Similar to $\mathrm{SD}$ , $\mathrm{AD}$ is defined as the coefficient of the linear term in the expansion of $\theta$ with respect to frequency:

(2) $$\begin{align}\mathrm{AD}:= {\left.\frac{\mathrm{d}\theta }{\mathrm{d}\Omega}\right|}_{\Omega ={\Omega}_0}={\theta}^{\prime }.\end{align}$$

We deduce the laser’s initial spectral phase $\varphi$ from the spectral phase $\phi$ of a plane wave of frequency $\Omega$ propagating at an angle $\theta$ with respect to the $z$ -axis:

$$\begin{align*}\phi \left(x,z,\Omega \right)=\frac{\Omega}{c}\left(-x\sin \theta +z\cos \theta \right).\end{align*}$$

Expanding this about $\Omega \approx {\Omega}_0$ and evaluating at the focus position $z=0$ , the laser’s initial spectral phase $\varphi$ is obtained. Up to the third order it reads, cf. Appendix A.1,

$$\begin{align*}&\varphi \left(x,z=0,\Omega \right)\approx -\frac{x}{c}{\Omega}_0{\theta}^{\prime}\left(\Omega -{\Omega}_0\right)-\frac{1}{2}\frac{x}{c}\left(2{\theta}^{\prime }+{\Omega}_0{\theta}^{{\prime\prime}}\right){\left(\Omega -{\Omega}_0\right)}^2\\& \qquad -\frac{1}{6}\frac{x}{c}\left(3{\theta}^{{\prime\prime} }+{\Omega}_0{\theta^{\prime\prime\prime} }-{\Omega}_0{\theta^{\prime}}^3\right){\left(\Omega -{\Omega}_0\right)}^3\\& \qquad +\frac{1}{2}{\mathrm{GDD}}_{\mathrm{foc}}{\left(\Omega -{\Omega}_0\right)}^2+\frac{1}{6}{\mathrm{TOD}}_{\mathrm{foc}}{\left(\Omega -{\Omega}_0\right)}^3\\& \quad =: -\alpha \frac{x}{w_0}+\frac{1}{2}{\mathrm{GDD}}_{\mathrm{foc}}{\left(\Omega -{\Omega}_0\right)}^2+\frac{1}{6}{\mathrm{TOD}}_{\mathrm{foc}}{\left(\Omega -{\Omega}_0\right)}^3,\end{align*}$$

where

(3) $$\begin{align}\alpha \left(\Omega \right)&=\frac{w_0}{c}\left[{\Omega}_0{\theta}^{\prime}\left(\Omega -{\Omega}_0\right)+\frac{1}{2}\left(2{\theta}^{\prime }+{\Omega}_0{\theta}^{{\prime\prime}}\right){\left(\Omega -{\Omega}_0\right)}^2\right. \nonumber\\& \qquad\quad \left.+\frac{1}{6}\left(3{\theta}^{{\prime\prime} }+{\Omega}_0{\theta^{\prime\prime\prime} }-{\Omega}_0{\theta^{\prime}}^3\right){\left(\Omega -{\Omega}_0\right)}^3\right].\end{align}$$

The quantity $\alpha /{w}_0$ can be regarded as the series expansion of a frequency’s wave vector $x$ -component, ${k}_x=-\left(\Omega /c\right)\sin \theta \left(\Omega \right)\approx -\alpha \left(\Omega \right)/{w}_0$ .

The expansion of the spectral phase in the focus above includes values $\mathrm{GDD}_{\mathrm{foc}}$ and $\mathrm{TOD}_{\mathrm{foc}}$ at $z=0$ for group-delay dispersion and third-order dispersion in the focus, respectively. Generally, group-delay dispersion $\mathrm{GDD}$ and third-order dispersion $\mathrm{TOD}$ are defined as follows:

(4) $$\begin{align}\mathrm{GDD}:= {\left.\frac{{\mathrm{d}}^2\varphi }{\mathrm{d}{\Omega}^2}\right|}_{\Omega ={\Omega}_0},\end{align}$$

(5) $$\begin{align}\mathrm{TOD}:= {\left.\frac{{\mathrm{d}}^3\varphi }{\mathrm{d}{\Omega}^3}\right|}_{\Omega ={\Omega}_0},\end{align}$$

and evolve during propagation. Their values in the focus are determined from known values before the focusing mirror, emerging, for example, through material dispersion within the laser system, plus contributions from dispersion coupling through focusing, as will be shown later.

2.2 Field at some distance from the focus in the frequency–space domain

The field distribution outside the focus is obtained by propagating the initial field with the Fresnel diffraction integral for cylindrical waves^[ Reference Siegmann ^{41 ,} Reference Steiniger, Widera, Pausch, Debus, Bussmann and Schramm ^{43 ]}, cf. Appendix A.2,

(6) $$\begin{align} &\widehat{E}\left(x,z,\Omega \right)=\sqrt{\frac{\Omega}{2\pi c}}\frac{e^{-i\left(\frac{\Omega}{c}z-\frac{\pi }{4}\right)}}{\sqrt{z}}\underset{-\infty }{\overset{\infty }{\int }}\widehat{E}\left(\xi, z=0,\Omega \right){e}^{-i\frac{\Omega}{2 cz}{\left(x-\xi \right)}^2}\kern0.1em \mathrm{d}\xi \nonumber\\&\quad =\sqrt{\frac{\Omega}{2\pi c}}\frac{e^{-i\left(\frac{\Omega}{c}z-\frac{\pi }{4}\right)}}{\sqrt{z}}{\epsilon}_{\Omega}{e}^{-i\frac{1}{2}{\mathrm{GDD}}_{\mathrm{foc}}{\left(\Omega -{\Omega}_0\right)}^2}{e}^{-i\frac{1}{6}{\mathrm{TOD}}_{\mathrm{foc}}{\left(\Omega -{\Omega}_0\right)}^3}\nonumber\\& \qquad \times\underset{-\infty }{\overset{\infty }{\int }}{\epsilon}_x\left(\xi \right){e}^{i\alpha \frac{\xi }{w_0}}{e}^{-i\frac{\Omega}{2 cz}{\left(x-\xi \right)}^2}\kern0.1em \mathrm{d}\xi \nonumber\\&\quad ={\epsilon}_{\Omega}{\left(1+\frac{z^2}{z_{\mathrm{R}}^2}\right)}^{-1/4}{e}^{-{\left[x-\left({x}_0-\frac{c}{\Omega_0{w}_0}\alpha z\right)\right]}^2\left[\frac{1}{w_0^2\left(1+{z}^2/{z}_{\mathrm{R}}^2\right)}+i\frac{\Omega}{2c}\frac{z}{\left({z}^2+{z}_{\mathrm{R}}^2\right)}\right]}\nonumber\\& \qquad \times {e}^{-i\frac{\Omega}{c}z}{e}^{i\alpha \frac{x}{w_0}}{e}^{i\frac{\alpha^2}{4}\frac{z}{z_{\mathrm{R}}}}{e}^{i\frac{1}{2}\arctan \frac{z}{z_{\mathrm{R}}}}{e}^{-i\frac{1}{2}{\mathrm{GDD}}_{\mathrm{foc}}{\left(\Omega -{\Omega}_0\right)}^2}\nonumber\\& \qquad \times {e}^{-i\frac{1}{6}{\mathrm{TOD}}_{\mathrm{foc}}{\left(\Omega -{\Omega}_0\right)}^3},\end{align}$$

where ${z}_{\mathrm{R}}=\Omega {w}_0^2/(2c)$ is the Rayleigh length, ${\lambda}_0=2\pi c/{\Omega}_0$ is the central laser wavelength and the well-known width $w(z)$ and radius of curvature $R(z)$ of the propagating laser pulse can be identified as

(7) $$\begin{align}w(z)={w}_0\sqrt{1+\frac{z^2}{z_{\mathrm{R}}^2}},\end{align}$$

(8) $$\begin{align}R(z)=z\left(1+\frac{z_{\mathrm{R}}^2}{z^2}\right).\end{align}$$

While these expressions for $w$ and $R$ are frequency dependent in general, we set ${z}_{\mathrm{R}}\approx \pi {w}_0^2/{\lambda}_0$ to good approximation in Equation (6) for the following calculations. Equation (6) is a well-known result^[ Reference Akturk, Gu, Zeek and Trebino ^{44 ]}. See Appendix A for details of this and the following derivations.

As is evident from the proportionality of the laser’s Gaussian transverse profile center ${x}_{\mathrm{c}}\left(z,\Omega \right)={x}_0-\alpha zc/\left({\Omega}_0{w}_0\right)$ to $\alpha$ in Equation (6), a frequency’s spatial distribution center is subject to higher-order dispersion. From this, the scaling of spatial dispersion with distance from the focus can be derived using Equation (1), which reads to the first order as

$$\begin{align*}\mathrm{SD}(z)={\mathrm{SD}}_{\mathrm{foc}}-{\mathrm{AD}}_{\mathrm{foc}}z.\end{align*}$$

Furthermore, Equation (6) allows identifying the advancement of higher-order dispersion with distance from the focus by performing the respective number of derivatives of the spectral phase $\varphi \left(x,z,\Omega \right)=- \mathrm{Arg}\left[\widehat{E}\left(x,z,\Omega \right)\right]$ with respect to $\Omega$ and evaluating at $\Omega ={\Omega}_0$ . Accordingly, advancements of $\mathrm{GDD}$ and $\mathrm{TOD}$ with $z$ are obtained using Equations (4) and (5), respectively, cf. Appendix A.3,

(9) $$\begin{align}\mathrm{GDD}(z)={\mathrm{GDD}}_{\mathrm{foc}}+4\frac{x}{w}{\beta}_3{\beta}_5+2{\Omega}_0\left(2\frac{x}{w}{\beta}_4+{\beta}_3^2\right){\beta}_5-2{\beta}_6,\end{align}$$

(10) $$\begin{align}\mathrm{TOD}(z)&={\mathrm{TOD}}_{\mathrm{foc}}+12\frac{x}{w}{\beta}_4{\beta}_5+6{\beta}_3^2{\beta}_5+12{\Omega}_0\frac{x}{w}{\beta}_5{\delta}_1\nonumber\\& \quad +12{\Omega}_0{\beta}_3{\beta}_4{\beta}_5-6{\delta}_2,\end{align}$$

where

$$\begin{align*}{\delta}_1&=\frac{z}{6w{\Omega}_0}\left(3{\theta}^{{\prime\prime} }+{\Omega}_0{\theta^{\prime\prime\prime} }-{\Omega}_0{\theta^{\prime}}^3-{x^{\prime\prime\prime}}_0\right),\\[2pt]{\delta}_2&=\frac{1}{2c}\left[{\theta}^{\prime}\left(2{\theta}^{\prime }+{\Omega}_0{\theta}^{{\prime\prime}}\right)z+\frac{1}{3}\left(3{\theta}^{{\prime\prime} }+{\Omega}_0{\theta^{\prime\prime\prime} }-{\Omega}_0{\theta^{\prime}}^3\right)x\right],\end{align*}$$

making use of the definitions in Equation (13) given below.

Equations (9) and (10) are more complex than those typically used^[ Reference Akturk, Gu, Zeek and Trebino ^{44 ]} and exhibit a variation over the transverse pulse profile either due to angular dispersion or the combination of spatial dispersion and diffraction or both. Moreover, even along the laser propagation axis ( $x=0$ ) spatial dispersion contributes to group-delay dispersion:

(11) $$\begin{align}{\left. \mathrm{GDD}(z)\right|}_{x=0}={\mathrm{GDD}}_{\mathrm{foc}}+\frac{\Omega_0}{c}\frac{\mathrm{SD}{(z)}^2}{R}-\frac{\Omega_0}{c}{\mathrm{AD}}_{\mathrm{foc}}^2z.\end{align}$$

This contribution compensates phase run-up outside the focus for off-axis traveling frequencies by taking phase front curvature into account. Phase run-up outside the focus originates from the term proportional to $\mathrm{AD}_{\mathrm{foc}}^2z$ , which itself represents a correction of phase due to a corrected traveling distance for off-axis traveling frequencies. Since this traveling distance correction is based upon a plane wave assumption, it is only valid near the focus, where $z\ll {z}_{\mathrm{R}}$ , and the correction by the term $\propto {\mathrm{SD}}^2/R$ is necessary. Far from the focus, where $z\gg {z}_{\mathrm{R}}$ and $R(z)\approx z$ , the two corrections cancel each other out in the case of vanishing spatial dispersion in the focus: ${\left. \mathrm{GDD}\left(z\gg {z}_{\mathrm{R}}\right)\right|}_{x=0,{\mathrm{SD}}_{\mathrm{foc}}=0}={\mathrm{GDD}}_{\mathrm{foc}}$ .

The above form of the initial field in the focus $E\left(x,z=0,\Omega \right)$ assumes that all frequencies focus at the same position $z=0$ along the central frequency’s propagation direction. This holds as long as the phase fronts of the expanded laser pulse, which is focused by the OAP, are flat. Typically this requires keeping the distance between the last telescope in the laser system and the OAP well below the Rayleigh range of the expanded laser pulse. If this is not the case, chromatic aberration will occur and further distort the pulse, as has been studied for focusing by a lens^[ Reference Federico and Martinez ^{45 ]}.

2.3 Field at some distance from the focus in the time–space domain

The field distribution in the time–space domain is obtained by Fourier transforming the above field distribution in the frequency domain (Equation (6)) to the time domain:

$$\begin{align*}E\left(x,z,t\right)=\frac{1}{2\pi}\int \widehat{E}\left(x,z,\Omega \right){e}^{i\Omega t}\mathrm{d}\Omega .\end{align*}$$

The result presented in the following allows for the first time to read off analytical relations for the scaling of pulse-front tilt and pulse duration valid in the close vicinity, as well as far from the focus.

In order to perform the Fourier transform, the in-focus transverse distribution center ${x}_0$ of a frequency is expanded up to the second order, ${x}_0\approx {x}_0^{\prime}\left(\Omega -{\Omega}_0\right)+\frac{1}{2}{x}_0^{{\prime\prime} }{\left(\Omega -{\Omega}_0\right)}^2$ , and the definition in Equation (3) of $\alpha$ is inserted in the complex argument of Equation (6), allowing one to order terms in powers of $\Omega -{\Omega}_0$ . Neglecting every contribution of the third order and higher, cf. Equations (98)–(129) in Appendix A.3,

(12) $$\begin{align} &\widehat{E}\left(x,z,\Omega \right)={\left(1+\frac{z^2}{z_{\mathrm{R}}^2}\right)}^{-1/4}{e}^{-\frac{x^2}{w^2}}{e}^{-i{\Omega}_0\frac{x^2}{2 cR}}{e}^{-i\frac{\Omega_0}{c}z}{e}^{i\frac{1}{2}\arctan \frac{z}{z_{\mathrm{R}}}}\nonumber\\& \quad \times {e}^{-\left[\left({\beta}_1+2\frac{x}{w}{\beta}_4+{\beta}_3^2\right)+i\left(\frac{1}{2}{\mathrm{GDD}}_{\mathrm{foc}}+2\frac{x}{w}{\beta}_3{\beta}_5+\left(2\frac{x}{w}{\beta}_4+{\beta}_3^2\right){\Omega}_0{\beta}_5-{\beta}_6\right)\right]{\left(\Omega -{\Omega}_0\right)}^2}\nonumber\\& \quad \times {e}^{-\left[2\frac{x}{w}{\beta}_3+i\left({\beta}_2+\frac{x^2}{w^2}{\beta}_5+2{\Omega}_0\frac{x}{w}{\beta}_3{\beta}_5\right)\right]\left(\Omega -{\Omega}_0\right)},\end{align}$$

where

(13) $$\begin{align} {\beta}_1&=\frac{\tau_0^2}{4}\nonumber,\\{\beta}_2&=\frac{z}{c}-{\Omega}_0{\theta}^{\prime}\frac{x}{c}\nonumber,\\{\beta}_3&=-\frac{\mathrm{SD}(z)}{w}\nonumber,\\{\beta}_4&=\frac{1}{2w}\left(2{\theta}^{\prime}\frac{z}{\Omega_0}+{\Omega}_0{\theta}^{{\prime\prime}}\frac{z}{\Omega_0}-{x}_0^{{\prime\prime}}\right)\nonumber,\\{\beta}_5&=\frac{w^2}{2 cR}\nonumber,\\{\beta}_6&=\frac{1}{2c}\left[{\Omega}_0{\theta^{\prime}}^2z+\left(2{\theta}^{\prime }+{\Omega}_0{\theta}^{{\prime\prime}}\right)x\right],\end{align}$$

and the approximated field can be analytically transformed to the time domain. The assumption of vanishing third- and higher-order dispersion for a particular setup can be verified with the help of Equation (123) from Appendix A. From this, it becomes clear that third-order contributions to the envelope and phase are negligible if $128\cdot \left[\left(x/w\right){\delta}_1+{\beta}_3{\beta}_4\right]/ {\tau}_0^3\ll 1$ and $11\cdot \mathrm{TOD}(z)/{\tau}_0^3\ll 1$ , respectively, which assumes that the spectral amplitude is only significant for frequencies $\left|\Omega -{\Omega}_0\right|\le 4/{\tau}_0$ (the amplitude falls below ${e}^{-4}$ of its initial value for a larger frequency deviation). In practice, these requirements are fulfilled for standard high-power, ultra-short laser pulses. For example, the requirements take absolute values of $3\times {10}^{-6}$ and $1\times {10}^{-6}$ , respectively, when evaluated at a Rayleigh length distance from the focus at the pulse center for a pulse of wavelength ${\lambda}_0=800$ nm and duration ${\tau}_{\mathrm{FWHM},\mathrm{I}}=5$ fs ( ${\tau}_0=4.25$ fs), being tightly focused to ${w}_0=2$ μm and angularly dispersed in the focus $\mathrm{AD}_{\mathrm{foc}}=1$ μrad/nm.

Further defining

$$\begin{align*} {\gamma}_1&=1+8\frac{x}{w}\frac{\beta_4}{\tau_0^2}+4\frac{\beta_3^2}{\tau_0^2},\\{\gamma}_2&=\left[\frac{1}{2}{\mathrm{GDD}}_{\mathrm{foc}}+2\frac{x}{w}{\beta}_3{\beta}_5+\left(2\frac{x}{w}{\beta}_4+{\beta}_3^2\right){\Omega}_0{\beta}_5-{\beta}_6\right]\frac{4}{\tau_0^2}\\&= \mathrm{GDD}(z)\frac{2}{\tau_0^2},\\{\gamma}_3&=-2\frac{x}{w}\frac{\beta_3}{\tau_0}=2\frac{\mathrm{SD}(z)}{w^2{\tau}_0}x,\\{\gamma}_4&=\left(t-{\beta}_2-\frac{x^2}{w^2}{\beta}_5-2{\Omega}_0\frac{x}{w}{\beta}_3{\beta}_5\right)\frac{1}{\tau_0},\end{align*}$$

allows to write the field in the time domain in a compact form. The time–space domain field is, cf. Equations (130)–(135) in Appendix A.3,

(14) $$\begin{align} E\left(x,z,t\right)&=\frac{1}{\tau_0\sqrt{\pi }}{\left[\left(1+\frac{z^2}{z_{\mathrm{R}}^2}\right)\left({\gamma}_1^2+{\gamma}_2^2\right)\right]}^{-1/4}{e}^{i{\Omega}_0\left(t-\frac{z}{c}-\frac{x^2}{2 cR}\right)}\nonumber\\& \quad \times {e}^{i\frac{1}{2}\left(\arctan \frac{z}{z_{\mathrm{R}}}-\arctan \frac{\gamma_2}{\gamma_1}\right)} {e}^{-\frac{x^2}{w^2{\gamma}_1}\left(1+8\frac{x}{w}{\beta}_4/{\tau}_0^2\right)}\nonumber\\& \quad \times {e}^{-\frac{{\left[{\tau}_0{\gamma}_4-\frac{\left({\tau}_0{\gamma}_3\right)\left({\tau}_0^2{\gamma}_2\right)}{\tau_0^2{\gamma}_1}\right]}^2}{\tau_0^2\left({\gamma}_1+{\gamma}_2^2/{\gamma}_1\right)}}{e}^{i\frac{\left({\gamma}_4^2-{\gamma}_3^2\right){\gamma}_2+2{\gamma}_3{\gamma}_4{\gamma}_1}{{\gamma}_1^2+{\gamma}_2^2}},\nonumber\\[-14pt] \end{align}$$

provided ${\gamma}_1>0$ , otherwise the Fourier transform over the Gaussian spectrum cannot be performed analytically since the frequency–space domain field (Equation (12)) grows exponentially with ${\left(\Omega -{\Omega}_0\right)}^2$ . For a detailed explanation, see Appendix A.3, Equation (130). Future work may model the spectrum with a different function in order to remove the requirement ${\gamma}_1>0$ .

The only problematic term with respect to the requirement ${\gamma}_1>0$ is the middle term in ${\gamma}_1$ being proportional to ${\beta}_4$ , which also appears in the nominator of the exponent of the transverse profile scaling as ${e}^{-{x}^2}$ in Equation (14). In general, this term cannot be neglected and its contribution can become significant in certain regimes, for example, for pulses with a duration of the order of only a few femtoseconds or shorter. These regimes demand to verify ${\gamma}_1>0$ when using the analytic expression for the total field or those for the pulse’s spatio-temporal properties further below.

There is, however, the ‘long pulse’ regime where the term proportional to ${\beta}_4$ can be neglected and ${\gamma}_1$ remains positive always. In this regime, $\left|8{\beta}_4/{\tau}_0^2\right|\ll 1$ , which can be rewritten as $8\pi \left|{\Omega}_0{\mathrm{AD}}_{\mathrm{foc}}\right|\left({w}_0/{\lambda}_0\right){\left({\Omega}_0{\tau}_0\right)}^{-2}\ll 1$ , with $\left|{\Omega}_0{\mathrm{AD}}_{\mathrm{foc}}\right|=\left|\tan {\psi}_{\mathrm{tilt},{\mathrm{AD}}_{\mathrm{foc}}}\right|$ representing pulse-front tilt in the focus due to $\mathrm{AD}_{\mathrm{foc}}$ alone. That is, the middle term proportional to ${\beta}_4$ will not be of relevance in ${\gamma}_1$ as long as the $\mathrm{AD}_{\mathrm{foc}}$ induced angle of pulse-front tilt ${\psi}_{\mathrm{tilt},{\mathrm{AD}}_{\mathrm{foc}}}$ satisfies $\left|\tan {\psi}_{\mathrm{tilt},{\mathrm{AD}}_{\mathrm{foc}}}\right|\ll {\lambda}_0{\left({\Omega}_0{\tau}_0\right)}^2/\left(8\pi {w}_0\right)$ , meaning that the tilt angle needs to be of the order of the ratio of the pulse duration (measured in number of laser oscillations) over the pulse width (measured in wavelengths) and provided that the pulse duration extends over several laser oscillations. Exemplarily, for a ${\lambda}_0=0.8$ μm, ${\tau}_{\mathrm{FWHM},\mathrm{I}}=30$ fs ( ${\tau}_0=25.5$ fs) pulse with a focal width of $\pi {w}_0\equiv 60{\lambda}_0$ , the ‘long pulse’ regime is reached if ${\psi}_{\mathrm{tilt},{\mathrm{AD}}_{\mathrm{foc}}}\ll {82}^{\circ }$ , and the requirement relaxes further for smaller focal spot diameters.

To our knowledge, the term $8\left(x/w\right)\left({\beta}_4/{\tau}_0^2\right)$ in ${\gamma}_1$ has not been taken into account in previous analysis of spatio-temporal couplings and its appearance outside the long pulse regime could only be recognized from the fully analytic treatment presented here.

While expressions for typically interesting intensity-related pulse parameters are derived from the time–space domain field (Equation (14)) in the following, it has several more areas of applicability. For example, one can derive the phase-related wavefront rotation^[ Reference Akturk, Gu, Gabolde and Trebino ^{29 ]} or feed the field into self-consistent simulations of pulse propagation or laser–matter interaction.

2.4 Duration, width and tilt of the propagating pulse

From Equation (14) the duration $T$ and width $W$ of the propagating Gaussian laser pulse with spatial, angular and group-delay dispersion in the focus are readily identified. These are the denominators of the fractions in the exponents of the last and next to last real exponential:

(15) $$\begin{align}{\tau}^2&={\tau}_0^2{\gamma}_1={\tau}_0^2\left[1+8\frac{x}{w}\frac{\beta_4}{\tau_0^2}+4\frac{\mathrm{SD}{(z)}^2}{w^2{\tau}_0^2}\right], \end{align}$$

(16) $$\begin{align}{T}^2&={\tau}_0^2\left({\gamma}_1+\frac{\gamma_2^2}{\gamma_1}\right)={\tau}^2+4\frac{\mathrm{GDD}{(z)}^2}{\tau^2},\end{align}$$

(17) $$\begin{align}{W}^2&={w}^2\frac{\tau^2}{\tau_0^2+8\frac{x}{w}{\beta}_4}.\end{align}$$

However, $W$ generally is not a typical Gaussian pulse width, as it still depends on the transverse coordinate $x$ . This rather shows that the transverse envelope does not keep a Gaussian shape during propagation but evolves to something more complex. (By setting $x=W$ in Equation (17) and solving the resulting cubic equation in $W/w$ it is possible to yield a value for $W$ that corresponds to its original meaning for a Gaussian beam, that is, as the distance from the pulse center along the transverse direction where the intensity reduces to $1/{e}^2$ compared to its center value.) Yet, these deviations from a Gaussian profile are not of relevance in the long pulse regime where the term proportional to ${\beta}_4$ can be neglected. Then $W$ quantifies the width of a normal Gaussian transverse profile. That is, the laser pulse keeps a Gaussian transverse profile and the spatio-temporal couplings do not alter the transverse profile to something more complex during propagation.

The expression for pulse duration (Equation (16)) is structurally equal to previously published results^[ Reference Akturk, Gu, Zeek and Trebino ^{44 ]}, but comprises more complex expressions for $\tau$ and $\mathrm{GDD}(z)$ , Equations (15) and (9), respectively. In the long pulse regime, $\tau$ assumes the well-known form ${\tau}^2={\tau}_0^2+4 \mathrm{SD}{(z)}^2/{w}^2$ , and represents pulse elongation due to spatial dispersion alone. In cases where pulse elongation takes place via group velocity dispersion in a dispersive material, the proportion of spatial dispersion is zero and $\tau ={\tau}_0$ .

From the numerator of the exponent of the last real exponential in Equation (14) the time delay ${t}_0$ of the pulse maximum can be identified:

$$\begin{align*}{\tau}_0{\gamma}_4-\frac{\left({\tau}_0{\gamma}_3\right)\left({\tau}_0^2{\gamma}_2\right)}{\tau_0^2{\gamma}_1}=: t-{t}_0,\end{align*}$$

where

$$\begin{align*}{t}_0=\frac{z}{c}-{\Omega}_0{\mathrm{AD}}_{\mathrm{foc}}\frac{x}{c}+\frac{x^2}{2 cR}-\frac{\Omega_0}{c}\frac{\mathrm{SD}(z)}{R}x+4\frac{\mathrm{SD}(z)}{w^2}\frac{\mathrm{GDD}(z)}{\tau^2}x.\end{align*}$$

The time delay is directly connected to the pulse-front tilt by

$$\begin{align*}\tan {\psi}_{\mathrm{tilt}}={\left.\frac{\mathrm{d}\left({ct}_0\right)}{\mathrm{d}x}\right|}_{x=0},\end{align*}$$

which yields, cf. Appendix A.4,

(18) $$\begin{align}\tan {\psi}_{\mathrm{tilt}}=-{\Omega}_0{\mathrm{AD}}_{\mathrm{foc}}-{\Omega}_0\frac{\mathrm{SD}(z)}{R}+4c\frac{\mathrm{SD}(z)}{w^2}{\left[\frac{\mathrm{GDD}(z)}{\tau^2}\right]}_{x=0}.\end{align}$$

In this expression, the first term represents a constant base value of pulse-front tilt due to angular dispersion, which is the true value of pulse-front tilt in the center of the focal plane^[ Reference Martinez ^{27 ]}. The remaining terms represent deviations from the focal plane center value due to radial offset of the point of evaluation or pulse propagation.

The second term is zero in the focus, but non-zero outside. For a specific frequency, it represents an effective angle of propagation due to increasing SD during propagation, just as AD represents an angle of propagation. It can be the major source of pulse-front tilt outside the focus, as observed for the setups in the next section. Its derivation is a main result of this work.

The structure of the third term is in line with previous findings^[ Reference Akturk, Gu, Zeek and Trebino ^{44 ]}. However, the definition for ${\left. \mathrm{GDD}(z)\right|}_{x=0}$ is extended in this work by the contribution of spatial dispersion, that is, the term proportional to $\mathrm{SD}^2/R$ in Equation (11).

Note that the definition of pulse-front tilt is not unique. The above definition is with respect to time delay ${t}_0$ of the pulse maximum along the transverse direction at some position $z$ , but pulse-front tilt can be defined with respect to longitudinal spatial offset ${z}_0$ between the pulse maximum and pulse center along the transverse direction at some time $t$ , too. The relation between the two definitions is

$$\begin{align*}\tan {\alpha}_{\mathrm{tilt}}={\left.\frac{\mathrm{d}\left({z}_0\right)}{\mathrm{d}x}\right|}_{x=0}=-\tan {\psi}_{\mathrm{tilt}}.\end{align*}$$

3.1 Angular dispersion

In the focus, the rays of frequency $\Omega$ and ${\Omega}_0$ enclose the propagation angle $\theta$ being required to calculate angular dispersion by Equation (2). The propagation angle is determined from the difference between the angles enclosed by the OAP’s optical axis and the deflected rays of $\Omega$ and ${\Omega}_0$ . Since there is angular dispersion already present before deflection at the mirror, the angle enclosed by the deflected ray of frequency $\Omega$ and the OAP’s optical axis is ${\psi}_{\mathrm{defl}}-{\theta}_{\mathrm{in}}$ , which leads to

$$\begin{align*}\theta \left(\Omega \right)={\psi}_{\mathrm{defl}}-{\theta}_{\mathrm{in}}-{\psi}_{\mathrm{defl},0}.\end{align*}$$

The deflection angle of frequency $\Omega$ is given by

(19) $$\begin{align}{\psi}_{\mathrm{defl}}=2\delta,\end{align}$$

where the tangent of $\delta$ can be determined from the slope of the mirror surface at the position of incidence $\xi$ :

(20) $$\begin{align}\delta =\arctan \frac{\xi }{2f}.\end{align}$$

The position of incidence is obtained by computing the intersection point between the ray and the mirror surface, that is, by equating

$$\begin{align*}\left({z}_{\mathrm{ray}}+\frac{\xi_0^2}{4f}\right)\tan {\theta}_{\mathrm{in}}=\xi -\left({\xi}_0-{x}_{\mathrm{in}}\right) \quad\mathrm{and}\quad {z}_{\mathrm{OAP}}=-\frac{\xi^2}{4f},\end{align*}$$

where the $z$ -axis points along the axis of propagation of the incident central frequency ray but originates at the vertex of the parabola. The resulting equation for the incidence position is

$$\begin{align*} 0&=\frac{\tan {\theta}_{\mathrm{in}}}{4f}{\xi}^2+\xi -\left({\xi}_0-{x}_{\mathrm{in}}\right)-\frac{\tan {\theta}_{\mathrm{in}}}{4f}{\xi}_0^2\\\iff 0&=a\frac{\xi^2}{f^2}+b\frac{\xi }{f}+c,\end{align*}$$

where

$$\begin{align*}a&=\frac{\tan {\theta}_{\mathrm{in}}}{4},\\b&=1,\\c&=-\frac{\xi_0-{x}_{\mathrm{in}}}{f}-\frac{\tan {\theta}_{\mathrm{in}}}{4}\frac{\xi_0^2}{f^2}. \end{align*}$$

This quadratic equation in $\xi /f$ has the solution

(21) $$\begin{align} \kern-12pt\xi &=2f\frac{-1+\sqrt{1-\tan {\theta}_{\mathrm{in}}c}}{\tan {\theta}_{\mathrm{in}}}\nonumber\\&\approx p+\left(q-\frac{p^2}{4f}\right){\theta}_{\mathrm{in}},\ \mathrm{where}\;p={\xi}_0-{x}_{\mathrm{in}}\;\mathrm{and}\;q=\frac{\xi_0^2}{4f},\end{align}$$

with which $\delta$ and thus ${\psi}_{\mathrm{defl}}$ can be calculated for any frequency $\Omega$ , cf. Equations (20) and (19), respectively. We assume ${\xi}_0$ to be given from the manufactured deflection angle and effective focal distance for the central frequency:

$$\begin{align*}{\xi}_0={f}_{\mathrm{eff},0}\sin {\psi}_{\mathrm{defl},0}.\end{align*}$$

With the above solution for the incidence point on the parabola surface, angular dispersion in the focus can be calculated:

(22) $$\begin{align}\mathrm{AD}_{\mathrm{foc},\mathrm{coupl}}&=\frac{\mathrm{d}}{\mathrm{d}\Omega}{\left[2\arctan \left(\frac{\xi }{2f}\right)-{\theta}_{\mathrm{in}}-{\psi}_{\mathrm{d}\mathrm{efl},0}\right]}_{\Omega ={\Omega}_0}\nonumber\\ &=-\frac{1}{f_{\mathrm{eff},0}}{x}_{\mathrm{in}}^{\prime }-{\theta}_{\mathrm{in}}^{\prime }.\end{align}$$

3.2 Spatial dispersion

Calculating spatial dispersion according to Equation (1) requires one to determine the spatial offset ${x}_0$ of frequency $\Omega$ in the focal plane. According to Figure 3, the spatial offset ${x}_0$ can be determined from ${\tilde{x}}_0$ :

$$\begin{align*}{x}_0=\frac{{\tilde{x}}_0}{\cos \theta },\end{align*}$$

which is itself determined by ${\tilde{x}}_0={f}_{\mathrm{eff}}\sin {\theta}_{\mathrm{in}}$ . Thus,

(23) $$\begin{align}\mathrm{SD}_{\mathrm{foc},\mathrm{coupl}}=\frac{\mathrm{d}}{\mathrm{d}\Omega}{\left(\frac{f_{\mathrm{eff}}\sin {\theta}_{\mathrm{in}}}{\cos \theta}\right)}_{\Omega ={\Omega}_0}={f}_{\mathrm{eff},0}{\theta}_{\mathrm{in}}^{\prime }.\end{align}$$

3.3 Group-delay dispersion

Calculating group-delay dispersion according to Equation (4) requires one to determine the phase advance of every frequency from the incidence plane to the focal plane, which can be calculated from a frequency’s optical path length. The path of a ray starts where its phase front intersects with the incidence position of the central frequency ray on the mirror surface and it ends where its phase front intersects with the focus (see Figure 3). The path length of a frequency $\Omega$ is divided into two sections, ${L}_{\mathrm{in}}$ and ${L}_{\mathrm{foc}}$ . The former is the distance from the starting point until the ray intersects with the parabola surface, while the latter is the distance from the parabola surface until the focal plane. The phase advance is

(24) $$\begin{align}\varphi \left(\Omega \right)=\frac{\Omega}{c}\left({L}_{\mathrm{in}}+{L}_{\mathrm{foc}}\right),\end{align}$$

where

$$\begin{align*}{L}_{\mathrm{in}}\left(\Omega \right)=-{x}_{\mathrm{in}}\sin {\theta}_{\mathrm{in}}+\frac{\xi_0^2-{\xi}^2}{4f\cos {\theta}_{\mathrm{in}}},\kern1em {L}_{\mathrm{foc}}\left(\Omega \right)={f}_{\mathrm{eff}}\cos {\theta}_{\mathrm{in}}, \end{align*}$$

with which

(25) $$\begin{align}\mathrm{GDD}_{\mathrm{foc},\mathrm{coupl}}={\left.\frac{{\mathrm{d}}^2\varphi }{\mathrm{d}{\Omega}^2}\right|}_{\Omega ={\Omega}_0}=-\frac{\Omega_0}{c}\left({f}_{\mathrm{eff},0}{\theta_{\mathrm{in}}^{\prime}}^2+2{\theta}_{\mathrm{in}}^{\prime }{x}_{\mathrm{in}}^{\prime}\right).\end{align}$$

3.4 Third-order dispersion

For future real and numerical experiments the value of third-order dispersion in the focus can be of interest. It is evaluated by applying Equation (5) on the phase advance (Equation (24)):

(26) $$\begin{align}\mathrm{TOD}_{\mathrm{foc},\mathrm{coupl}}={\left.\frac{{\mathrm{d}}^3\varphi }{\mathrm{d}{\Omega}^3}\right|}_{\Omega ={\Omega}_0}=3\frac{\theta_{\mathrm{in}}^{\prime }}{c}\left({\Omega}_0{\xi}_0\frac{\theta_{\mathrm{in}}^{\prime }{x}_{\mathrm{in}}^{\prime }}{f}-{f}_{\mathrm{eff},0}{\theta}_{\mathrm{in}}^{\prime }-2{x}_{\mathrm{in}}^{\prime}\right).\end{align}$$

4.1 Short focal length setup

This setup’s OAP has ${f}_{\mathrm{eff},0}/{D}_{\mathrm{in}}=2.5$ ( $=f/\#$ ), focusing the incident pulse to a width ${w}_{\mathrm{FWHM},\mathrm{I}}=2.35$ μm and resulting in a Rayleigh length ${z}_{\mathrm{R}}=16$ μm.

Figure 4 visualizes pulse-front tilt and pulse duration in the course of propagation through the focus for angular dispersion values before focusing ranging from $\mathrm{AD}_{\mathrm{in}}=5\times {10}^{-3}$ to 1 μrad/nm without spatial dispersion before focusing, that is, $\mathrm{SD}_{\mathrm{in}}=0$ . While small values of $\mathrm{AD}_{\mathrm{in}}$ below ${10}^{-2}$ μrad/nm result in a maximum pulse-front tilt of $-{3.6}^{\circ }$ at a Rayleigh length before the focus, higher values such as $0.25$ μrad/nm result in a large maximum pulse-front tilt of $-{51}^{\circ }$ at about the same position. Angular dispersion before focusing of 1 μrad/nm results in an even larger maximum pulse-front tilt of $-{61}^{\circ }$ at $3.5$ Rayleigh lengths before the focus. Generally, it can be observed that larger values of $\mathrm{AD}_{\mathrm{in}}$ result in larger maximum pulse-front tilt farther away from the focus. In all of these examples, group-delay dispersion in the focus $\mathrm{GDD}_{\mathrm{foc},\mathrm{coupl}}$ due to $\mathrm{AD}_{\mathrm{in}}$ is negligible, as it is only $-0.2$ fs ${}^2$ for the largest $\mathrm{AD}_{\mathrm{in}}$ . To ease comparison to the numerical results shown later, the in-focus value $\mathrm{GDD}_{\mathrm{foc}}$ is therefore set to zero in the calculations.

Figure 4 Pulse-front tilt and pulse duration in the course of propagation of a $0.8$ μm, ${\tau}_{\mathrm{FWHM},\mathrm{I}}=30$ fs, ${D}_{\mathrm{in}}=100$ mm laser pulse through the focus of the short focal range setup without spatial dispersion before the focusing mirror. The colors of the lines represent angular dispersion values before focusing $\mathrm{AD}_{\mathrm{in}}=5\times {10}^{-3},1\times {10}^{-2},\mathrm{2.5}\times {10}^{-2},5\times {10}^{-2},\mathrm{0.1,0.25,0.5,1}$ μrad/nm. Originating from $\mathrm{AD}_{\mathrm{in}}$ , there is angular dispersion, and hence pulse-front tilt, in the focus $\mathrm{AD}_{\mathrm{foc}}=-\mathrm{AD}_{\mathrm{in}}$ . Correspondingly, the position of zero pulse-front tilt along the beamline is outside the focus, as shown in the inset. Since absolute values of pulse-front tilt in the focus $\mid {\psi}_{\mathrm{tilt}}\mid$ are below ${0.05}^{\circ }$ for all values of $\mathrm{AD}_{\mathrm{in}}$ , this offset is negligible in practice for this particular example.

The major source of these large pulse-front tilts is the appearance of spatial dispersion, that is, the term $-{\Omega}_0 \mathrm{SD}/R$ in Equation (18). In this term, $\mathrm{SD}$ and $R$ together define a maximum propagation angle, which at the same time is the maximum angle enclosed by a phase front and the laser propagation axis. Just as for $-{\Omega}_0{\theta}^{\prime }$ , this angle leads to a maximum time delay along the transverse direction and therefore pulse-front tilt. This pulse-front tilt caused by spatial dispersion varies during propagation due to the varying radius of curvature $R$ . It reaches its maximum at a Rayleigh length from the focus, where the respective time delay is largest due to $R$ being smallest, and it vanishes in the focus where $R$ is infinite such that there is no time delay.

The third term in Equation (18) constitutes a damping of the leading second term. For larger angular dispersion before focusing it provides for the shift of maximum pulse-front tilt to positions beyond the Rayleigh length, which is the position where the second term peaks.

In contrast to pulse-front tilt, the increase of pulse duration is only relevant for the two largest $\mathrm{AD}_{\mathrm{in}}$ values, with a maximum of $3.5{\tau}_0$ in the focus for $\mathrm{AD}_{\mathrm{in}}=1$ μrad/nm.

The source of pulse elongation is again spatial dispersion, described by Equation (15) alone since $\mathrm{GDD}$ is assumed to vanish in the focus. Spatial dispersion leads to a loss of overlap between spatial distributions of frequencies, which thins out the local spectrum. This effect is largest in the focus where the spatial frequency distributions are smallest, and thus the local spectrum is smallest and the pulse duration is longest.

The above setup neglects $\mathrm{SD}_{\mathrm{in}}$ , that is, spatial dispersion generated by angular dispersion during propagation from the laser system’s compressor until the OAP. Assuming 10 m distance from the compressor until the OAP, spatial dispersion before focusing at the OAP due to propagation with angular dispersion is $\mathrm{SD}_{\mathrm{in}}=-\mathrm{AD}_{\mathrm{in}}\cdot 10\ \mathrm{m}={-}0.05,{-}0.1,{-}0.25,{-}0.5,{-}1,{-}2.5,{-}5,{-}10$ μm/nm. This spatial dispersion before focusing will not influence spatial dispersion in the focus, according to Equation (23), but it will increase angular dispersion, and therefore pulse-front tilt, in the focus. Pulse-front tilts in the focus are ${\psi}_{\mathrm{tilt}}=\mathrm{0.01}^{\circ},\mathrm{0.02}^{\circ},\mathrm{0.04}^{\circ},\mathrm{0.09}^{\circ},\mathrm{0.18}^{\circ},\mathrm{0.45}^{\circ},\mathrm{0.90}^{\circ},\mathrm{1.79}^{\circ}$ , respectively. Since these are still small, the overall picture of the scaling remains equal compared to the setup with $\mathrm{SD}_{\mathrm{in}}=0$ . In particular, maximum values of pulse-front tilt and duration do not change.

4.2 Long focal range setup

This setup’s OAP has ${f}_{\mathrm{eff},0}/{D}_{\mathrm{in}}=250$ , focusing the incident pulse to a width ${w}_{\mathrm{FWHM},\mathrm{I}}=19$ μm and resulting in a Rayleigh length ${z}_{\mathrm{R}}=1.0$ mm.

Figure 5 visualizes pulse-front tilt and pulse duration in the course of propagation through the focus for the same range of angular dispersion values before focusing as for the short focal range setup and without spatial dispersion before focusing. Due to equal laser parameters, the scaling is qualitatively equal to the short focal range setup. Only the maximum value of pulse-front tilt is reduced, since the radius of the pulse-front curvature scales quadratically in the focal distance while spatial dispersion scales linearly for equal laser parameters before focusing. In total, this results in less time delay between frequencies along the transverse direction, reducing pulse-front tilt.

Figure 5 Pulse-front tilt and pulse duration in the course of propagation through the focus of the long focal range setup without spatial dispersion before focusing. Parameters are equal to the short focal range setup (see Figure 4).

Pulse duration in focus remains equal between long and short focal range setups, as the ratio of spatial dispersion and width in focus, which determines pulse elongation, is independent of focal length.

The considerations for group-delay dispersion in the focus and spatial dispersion before focusing outlined for the short focal range setup can be identically applied to this long focal range setup.